intersection_closed_polygons_xld
— Intersect closed polygons.
intersection_closed_polygons_xld(Polygons1, Polygons2 : PolygonsIntersection : : )
The operator intersection_closed_polygons_xld
calculates the
intersection of the regions enclosed by the polygons Polygons1
and
Polygons2
. The boundaries of this intersection are returned in
PolygonsIntersection
.
If the individual input polygons are not closed, they are closed automatically by connecting their start and end points.
Internally, first, the regions enclosed by each set of polygons
(Polygons1
and Polygons2
, respectively) are determined as
described below. Then, the intersection of these two regions is calculated.
In the following, the two sets of input polygons are referred to as
boundary sets. A boundary set consists of an arbitrary number of
boundaries (the individual polygons of Polygons1
and
Polygons2
, respectively). Each boundary may be convex or concave and
self-intersecting. Internal holes may be formed by the nesting of boundaries.
The region enclosed by such a boundary set is defined by the so-called Even-Odd-Rule. Thus, it consists of all points with the following property: The line constructed by connecting the point with another reference point that lies outside of the region has an odd number of intersections with boundaries.
More descriptive, this means that a boundary defines a hole in the region enclosed by another boundary if it lies completely inside that region. Similarly, the overlapping area of two separate boundaries of one boundary set is taken as a "hole", i.e., it does not belong to the region enclosed by the two boundaries. Note that the region enclosed by a boundary does not depend on the orientation of the boundary.
A self-intersecting boundary may be split at the intersection point or it is reordered such that it touches itself at the intersection point. The resulting boundaries are treated as separate boundaries.
The resulting polygons PolygonsIntersection
contain no references to
the XLD contours that are possibly referenced by Polygons1
and
Polygons2
. Hence, operators that access the contours associated with
a polygon, e.g., split_contours_xld
will not work correctly.
Polygons1
(input_object) xld_poly(-array) →
object
Polygons enclosing the first region to be intersected.
Polygons2
(input_object) xld_poly(-array) →
object
Polygons enclosing the second region to be intersected.
PolygonsIntersection
(output_object) xld_poly(-array) →
object
Polygons enclosing the intersection.
intersection_closed_polygons_xld
returns 2 (
H_MSG_TRUE)
if all parameters are
correct. If necessary, an exception is raised.
difference_closed_polygons_xld
,
symm_difference_closed_polygons_xld
,
union2_closed_polygons_xld
,
intersection_closed_contours_xld
Foundation